An apparatus for inspecting sidewall thickness of non-round transparent containers includes a conveyor for holding a container in stationary position and rotating the container around an axis. A light source directs light energy onto a sidewall of the container on the conveyor. An anamorphic lens system having a lens system axis directs onto a light sensor energy reflected from portions of the inside and outside surfaces of the container sidewall that are substantially parallel to the lens system axis. An information processor is responsive to the sensor for determining sidewall thickness at increments of container rotation as a function of separation at the sensor between light energies reflected from the inside and outside surfaces of the container sidewall.
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1. Apparatus for inspecting sidewall thickness of a non-round transparent container, which includes:
a conveyor for holding a container in stationary position and rotating the container around an axis,
a light source for directing light energy onto a sidewall of a container on said conveyor,
a light sensor and an anamorphic lens system having a lens system axis for directing onto said light sensor only light energy reflected from portions of the inside and outside surfaces of the container sidewall that are substantially parallel to said lens system axis, and
an information processor responsive to said sensor for determining sidewall thickness at increments of container rotation as a function of separation at said sensor between light energies reflected from the inside and outside surfaces of the container sidewall.
3. A method of inspecting sidewall thickness of a non-round container, which includes the steps of:
(a) holding the container in stationary position while rotating the container around an axis,
(b) directing a line-shaped light beam onto a sidewall of the container, said line-shaped light beam having a long dimension perpendicular to said axis,
(c) directing onto a light sensor only portions of said light beam reflected from inside and outside surfaces of the container sidewall that are substantially perpendicular to light energy directed onto the container sidewall as viewed from a direction parallel to said axis, and
(d) determining container sidewall thickness at increments of container rotation as a function of separation between light energy portions at said sensor reflected from the inside and outside surfaces of the container sidewall.
2. Apparatus for inspecting sidewall thickness of non-round transparent containers, which includes:
a conveyor for presenting containers in sequence and for holding each container in turn in stationary position while rotating the container around an axis,
a light source for directing light energy onto a sidewall of a container as the container is held and rotated on said conveyor,
a light sensor and an anamorphic lens system having a lens system axis for directing onto said light sensor only light energy reflected from inside and outside surface portions of the container sidewall that lie in planes substantially perpendicular to said lens system axis,
said light energy portions reflected from inside and outside surface portions of the container sidewall that lie in planes substantially perpendicular to the lens system axis sweeping back and forth along said lens system, as the container rotates, due to non-roundness of the container, and
an information processor responsive to said light sensor for determining sidewall thickness at increments of container rotation as a function of separation at said sensor between light energy portions reflected from the inside and outside surfaces of the container sidewall.
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The present disclosure is directed to inspection of transparent containers for commercial variations that affect optical properties of the containers, and more particularly to an apparatus and method for electro-optically measuring sidewall thickness of non-round transparent containers.
Electro-optical techniques have been employed for measuring sidewall thickness of transparent containers. For example, U.S. Pat. No. 6,806,459 discloses an apparatus and method for measuring sidewall thickness of a container, which includes a conveyor for moving the container transversely of its axis through an inspection station while simultaneously rotating the container around its axis by “rolling” the container along a rail at the inspection station. A light source and an illumination lens system direct onto the sidewall of the container a line-shaped light beam having a long dimension perpendicular to the axis of the container, parallel to the direction of movement through the inspection station and of sufficient length to illuminate the container sidewall as it is rolled along the rail at the inspection station. An anamorphic imaging lens system directs onto a light sensor light energy reflected from portions of the outside and inside sidewall surfaces that are perpendicular to the illumination light energy. An information processor is responsive to light energy directed onto the light sensor by the imaging lens system for determining the thickness of the container between the outside and inside sidewall surfaces as the container is rolled along the rail. Although the apparatus and method disclosed in the noted patent are well suited for measuring sidewall thickness of round containers, such apparatus and method are not well suited for measuring sidewall thickness of non-round containers that cannot be made to roll along the rail at the inspection station.
U.S. Pat. No. 5,291,271 discloses an apparatus and method for electro-optically measuring the thickness of a container wall. A light source directs a light beam onto the outside surface of the container at an angle such that a portion of the light beam is reflected from the outside surface, and a portion is refracted into the container wall, reflected from the inside wall surface and then re-emerges from the outside wall surface. A lens system is disposed between a light sensor and the container wall for focusing onto the sensor light energy reflected from the outside and inside wall surfaces. The lens system has an image plane in which the sensor is disposed and an object plane collinear with the illumination light beam. The container is held in stationary position and rotated around its axis. An information processor scans the sensor at increments of container rotation, and determines wall thickness of the container between the inside and outside surfaces as a function of the separation between the points of incidence of the reflected light energies on the sensor. Although the apparatus and method disclosed in this patent again is well suited for measuring sidewall thickness of round containers, such apparatus and method are not well suited for measuring sidewall thickness of non-round containers inasmuch as the illumination beam cannot track undulations in the sidewall of a non-round container as the container rotates. It is a general object of the present disclosure to provide an apparatus and method for measuring sidewall thickness of non-round transparent containers.
The present disclosure embodies a number of aspects that can be implemented separately from or in combination with each other.
An apparatus for inspecting sidewall thickness of non-round transparent containers, in accordance with one aspect of the present disclosure, includes a conveyor for holding a container in stationary position and rotating the container around an axis. A light source directs light energy onto a sidewall of the container on the conveyor. An anamorphic lens system having a lens system axis directs onto a light sensor energy reflected from portions of the inside and outside surfaces of the container sidewall that are substantially parallel to the lens system axis. The term “substantially parallel” means that the surfaces of the container sidewall are parallel to the lens system axis within a narrow acceptance angle of the lens system, such as an acceptance angle of 1° in an exemplary embodiment of the disclosure. An information processor is responsive to the sensor for determining sidewall thickness at increments of container rotation as a function of separation at the sensor between light energies reflected from the inside and outside surfaces of the container sidewall.
An apparatus for inspecting sidewall thickness of non-round transparent containers, in accordance with another aspect of the present disclosure, includes a conveyor for presenting containers in sequence and holding each container in turn in stationary position while rotating the container around an axis. A light source directs light energy onto a sidewall of a container as it is held and rotated on the conveyor. An anamorphic lens system having a lens system axis directs onto a light sensor portions of the light energy reflected from inside and outside surfaces of the container sidewall in planes substantially perpendicular to the lens system axis. The term “substantially perpendicular” refers to light energy reflected in planes perpendicular to the lens system axis within a narrow acceptance angle of the lens system, such as 1° in an exemplary embodiment of the disclosure. The light energy portions reflected from inside and outside surfaces of the container sidewall in planes substantially perpendicular to the lens system axis sweep back and forth along the anamorphic lens system, as the container rotates, due to the non-roundness of the container. An information processor is responsive to the light sensor for determining sidewall thickness at increments of container rotation as a function of separation at the sensor between light energy portions reflected from the inside and outside surfaces of the container sidewall.
A method of inspecting sidewall thickness of a non-round container, in accordance with a further aspect of the present disclosure, includes holding the container in stationary position while rotating the container around an axis. A line-shaped light beam is directed onto a sidewall of the container, with the line-shaped light beam having a long dimension perpendicular to the axis of rotation. Portions of the light beam reflected from inside and outside surfaces of the container sidewall that are substantially perpendicular to light energy directed onto the container sidewall, as viewed from a direction parallel to the axis, are directed onto a light sensor. Container sidewall thickness is determined at increments of container rotation as a function of separation at the sensor between light energy portions reflected from the inside and outside surfaces of the container sidewall.
The disclosure, together with additional objects, features, advantages and aspects thereof, will best be understood from the following description, the appended claims and the accompanying drawings, in which:
A light source 18 is disposed to direct light energy through an illumination lens system 20 onto the sidewall of container 12 held and rotated on conveyor 14. Light energy reflected from the inside and outside surfaces of the container sidewall are directed by an anamorphic imaging lens system 22 onto a light sensor 24. An information processor 26 is responsive to sensor 24 for determining sidewall thickness at increments of container rotation as a function of separation at the sensor between light energies reflected from the inside and outside surfaces of the container sidewall. Sidewall thickness information can be presented to an operator at a display 28 and/or can be used by the information processor to activate a reject mechanism associated with the conveyor for separating containers having a sidewall thickness outside of a desired range. Sidewall thickness data can, of course, be stored or otherwise used for production system analysis and control.
Referring now to
There thus have been disclosed an apparatus and method for determining sidewall thickness of a transparent non-round container that fully satisfy all of the objects and aims previously set forth. The disclosure has been presented in conjunction with an exemplary embodiment, and a number of modifications and variations have been discussed. Other modifications and variations readily will suggest themselves to persons of ordinary skill in the art in view of the foregoing discussion. For example, although container 12 in the exemplary embodiment of the disclosure has a rounded “square” sidewall geometry, it will be apparent that other non-round container sidewall geometries can be accommodated, including for example triangular geometries, oval geometries, flask-shaped geometries, etc. The disclosure is intended to embrace all such modifications and variations as fall within the spirit and broad scope of the appended claims.
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Jun 22 2006 | RINGLIEN, JAMES A | Owens-Brockway Glass Container Inc | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 018033 | /0627 | |
Jun 26 2006 | Owens-Brockway Glass Container Inc. | (assignment on the face of the patent) | / |
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